On the Maximal Displacement of Subcritical Branching Random Walks

Abstract

We study the maximal displacement of a one dimensional subcritical branching random walk initiated by a single particle at the origin. For each n∈N, let Mn be the rightmost position reached by the branching random walk up to generation n. Under the assumption that the offspring distribution has a finite third moment and the jump distribution has mean zero and a finite probability generating function, we show that there exists >1 such that the function \[ g(c,n):= cn P(Mn≥ cn), for each c>0 and n∈N, \] satisfies the following properties: there exist 0<δ≤ δ < ∞ such that if c<δ, then 0<n→∞ g (c,n)≤ n→∞ g (c,n) ≤ 1, while if c>δ, then \[ n→∞ g (c,n)=0. \] Moreover, if the jump distribution has a finite right range R, then δ < R. If furthermore the jump distribution is "nearly right-continuous", then there exists ∈ (0,1] such that n→ ∞g(c,n)= for all c<δ. We also show that the tail distribution of M:=n≥ 0Mn, namely, the rightmost position ever reached by the branching random walk, has a similar exponential decay (without the cutoff at δ). Finally, by duality, these results imply that the maximal displacement of supercritical branching random walks conditional on extinction has a similar tail behavior.